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authorDimitri Staessens <[email protected]>2020-12-12 10:27:57 +0100
committerDimitri Staessens <[email protected]>2020-12-12 10:27:57 +0100
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blog: Add post about congestion avoidance
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+---
+date: 2020-12-12
+title: "Congestion avoidance in Ouroboros"
+linkTitle: "Congestion avoidance"
+description: "API for congestion avoidance and the Ouroboros MB-ECN algorithm"
+author: Dimitri Staessens
+---
+
+The upcoming 0.18 version of the prototype has a bunch of big
+additions coming in, but the one that I'm most excited about is the
+addition of congestion avoidance. Now that the implementation is
+reaching its final shape, I just couldn't wait to share with the world
+what it looks like, so here I'll talk a bit about how it works.
+
+# Congestion avoidance
+
+Congestion avoidance is a mechanism for a network to avoid situations
+where the where the total traffic offered on a network element (link
+or node) systemically exceeds its capacity to handle this traffic
+(temporary overload due to traffic burstiness is not
+congestion). While bursts can be handled with adding buffers to
+network elements, the solution to congestion is to reduce the ingest
+of traffic at the network endpoints that are sources for the traffic
+over the congested element(s).
+
+I won't be going into too many details here, but there are two classes
+of mechanisms to inform traffic sources of congestion. One is Explicit
+Congestion Notification (ECN), where information is sent to the sender
+that its traffic is traversing a congested element. This is a solution
+that is, for instance, used by DataCenter TCP (DCTCP)[^1]. The other
+mechanism is implicit congestion detection, for instance by inferring
+congestion from packet loss (most TCP flavors) or increases in
+round-trip-time (TCP vegas).
+
+Once the sender is aware that its traffic is experiencing congestion,
+it has to take action. A simple (proven) way is the AIMD algorithm
+(Additive Increase, Multiplicative Decrease). When there is no sign of
+congestion, senders will steadily increase the amount of traffic they
+are sending (Additive Increase). When congestion is detected, they
+will quickly back off (Multiplicative Decrease). Usually this is
+augmented with a Slow Start (Multiplicative Increase) phase when the
+senders begins to send, to reach the maximum bandwidth more
+quickly. AIMD is used by TCP and QUIC (among others), and Ouroboros is
+no different. It's mathematically proven to work.
+
+Now that the main ingredients are known, we can get to the
+preparation of the course.
+
+# Ouroboros congestion avoidance
+
+Congestion avoidance is in a very specific location in the Ouroboros
+architecture: at the ingest point of the network; it is the
+responsibility of the network, not the client application. In
+OSI-layer terminology, we could say it's in "Layer 3", not in "Layer
+4".
+
+Congestion has to be dealt with for each individual traffic
+source/destination pair. In TCP this is called a connection, in
+Ouroboros we call it a _flow_.
+
+Ouroboros _flows_ are abstractions for the most basic of packet flows.
+A flow is defined by two endpoints and all that a flow guarantees is
+that there exist strings of bytes (packets) that, when offered at the
+ingress endpoint, have a non-zero chance of emerging at the egress
+endpoint. I say 'there exist' to allow, for instance, for maximum
+packet lengths. If it helps, think of flow endpoints as an IP:UDP
+address:port pair (but emphatically _NOT_ an IP:TCP address:port
+pair). There is no protocol assumed for the packets that traverse the
+flow. To the ingress and egress point, they are just a bunch of bytes.
+
+Now this has one major implication: We will need to add some
+information to these packets to infer congestion indirectly or
+explicitly. It should be obvious that explicit congestion notification
+is the simplest solution here. The Ouroboros prototype (currently)
+allows an octet for ECN.
+
+# Functional elements of the congestion API
+
+This section glances over the API in an informal way. A reference
+manual for the actual C API will be added after 0.18 is in the master
+branch of the prototype.
+
+When flows are created, some state can be stored, which we call the
+_congestion context_. For now it's not important to know what state is
+stored in that context. If you're familiar with the inner workings of
+TCP, think of it as a black-box generalization of the _tranmission
+control block_. Both endpoints of a flow have such a congestion
+context.
+
+At the sender side, the congestion context is updated for each packet
+that is sent on the flow. Now, the only information that is known at
+the ingress is 1) that there is a packet to be sent, and 2) the length
+of this packet. The call at the ingress is thus:
+
+```
+ update_context_at_sender <packet_length>
+```
+
+This function has to inform when it is allowed to actually send the
+packet, for instance by blocking for a certain period.
+
+At the receiver flow endpoint, we have a bit more information, 1) that
+a packet arrived, 2) the length of this packet, and 3) the value of
+the ECN octet associated with this packet. The call at the egress is
+thus:
+
+```
+ update_context_at_receiver <packet_length, ecn>
+```
+
+Based on this information, receiver can decide if and when to update
+the sender. We are a bit more flexible in what can be sent, at this
+point, the prototype allows sending a packet (which we call
+FLOW_UPDATE) with a 16-bit Explicit Congestion Experienced (ECE) field.
+
+This implies that the sender can get this information from the
+receiver, so it knows 1) that such a packet arrived, and 2) the value
+of the ECE field.
+
+```
+ update_context_at_sender_ece <ece>
+```
+
+That is the API for the endpoints. In each Ouroboros IPCP (think
+'router'), the value of the ECN field is updated.
+
+```
+ update_ecn_in_router <ecn>
+```
+
+That's about as lean as as it gets. Now let's have a look at the
+algorithm that I designed and implemented as part of the prototype.
+
+# The Ouroboros multi-bit Forward ECN (MB-ECN) algorithm
+
+The algorithm is based on the workings of DataCenter TCP
+(DCTCP). Before I dig into the details, I will list the main
+differences, without any judgement.
+
+* The rates for additive increase and slow start are the same
+ _constant_ for all flows (but could be made configurable for each
+ network layer if needed). This is achieved by having a window that
+ is independent of RTT. This may make it more fair, as congestion
+ avoidance in DCTCP (and in most -- if not all -- TCP variants), is
+ biased in favor of flows with smaller RTT[^1].
+
+* Because it is operating at the _flow_ level, it estimates the
+ _actual_ bandwidth sent, including retransmissions, ACKs and what
+ not from protocols operating on the flow. DCTCP estimates bandwith
+ based on which data offsets are acknowledged.
+
+* The algorithm uses 8 bits to indicate the queue depth in each
+ router, instead of a single bit (due to IP header restrictions) for
+ DCTCP.
+
+* MB-ECN sends a (small) out-of-band FLOW_UPDATE packet, DCTCP updates
+ in-band TCP ECN/ECE bits in acknowledgment (ACK) packets. Note that
+ DCTCP sends an immediate ACK with ECE set at the start of
+ congestion, and sends an immediate ACK with ECE not set at the end
+ of congestion. Otherwise, the ECE is set accordingly for any
+ "regular" ACKs.
+
+* The MB-ECN algorithm can be implemented without the need for
+ dividing numbers (apart from bit shifts). At least in the linux
+ kernel implementation, DCTCP has a division for estimating the
+ number of bytes that experienced congestion from the received acks
+ with ECE bits set. I'm not sure this can be avoided[^2].
+
+Now, on to the MB-ECN algorithm. The values for some constants
+presented here have only been quickly tested; a _lot_ more scientific
+scrutiny is definitely needed here to make any statements about the
+performance of this algorithm. I will just explain the operation, and
+provide some very preliminary measurement results.
+
+First, like DCTCP, the routers mark the ECN field based on the
+outgoing queue depth. The current minimum queue depth to trigger and
+ECN is 16 packets (implemented as a bit shift of the queue size when
+writing a packet). We perform a logical OR with the previous value of
+the packet. If the width of the ECN field would be a single bit, this
+operation would be identical.
+
+At the _receiver_ side, the context maintains two state variables.
+
+* The floating sum (ECE) of the value of the (8-bit) ECN field over the
+last 2<sup>N</sup> packets is maintained (currently N=5, so 32
+packets). This is a value between 0 and 2<sup>8 + 5</sup> - 1.
+
+* The number of packets received during a period of congestion. This
+ is just for internal use.
+
+If th ECE value is 0, no actions are performed at the receiver.
+
+If this ECE value becomes higher than 0 (there is some indication of
+start of congestion), an immediate FLOW_UPDATE is sent with this
+value. If a packet arrives with ECN = 0, the ECE value is _halved_.
+
+For every _increase_ in the ECE value, an immediate update is sent.
+
+If the ECE value remains stable or decreases, an update is sent only
+every M packets (currently, M = 8). This is what the counter is for.
+
+If the ECE value returns to 0 after a period of congestion, an
+immediate FLOW_UPDATE with the value 0 is sent.
+
+At the _sender_ side, the context keeps track of the actual congestion
+window. The sender keeps track of:
+
+* The current sender ECE value, which is updated when receiving a
+ FLOW_UPDATE.
+
+* A bool indicating Slow Start, which is set to false when a
+ FLOW_UPDATE arrives.
+
+* A sender_side packet counter. If this exceeds the value of N, the
+ ECE is reset to 0. This protects the sender from lost FLOW_UPDATES
+ that signal the end of congestion.
+
+* The window size multiplier W. For all flows, the window starts at a
+ predetermined size, 2<sup>W</sup> ns. Currently W = 24, starting at
+ about 16.8ms. The power of 2 allows us to perform operations on the
+ window boundaries using bit shift arithmetic.
+
+* The current window start time (a single integer), based on the
+ multiplier.
+
+* The number of packets sent in the current window. If this is below a
+ PKT_MIN threshold before the start of a window period, the new
+ window size is doubled. If this is above a PKT_MAX threshold before
+ the start of a new window period, the new window size is halved. The
+ thresholds are currently set to 8 and 64, scaling the window width
+ to average sending ~36 packets in a window. When the window scales,
+ the value for the allowed bytes to send in this window (see below)
+ scales accordingly to keep the sender bandwidth at the same
+ level. These values should be set with the value of N at the
+ receiver side in mind.
+
+* The number bytes sent in this window. This is updated when sending
+ each packet.
+
+* The number of allowed bytes in this window. This is calculated at
+ the start of a new window: doubled at Slow Start, multiplied by a
+ factor based on sender ECE when there is congestion, and increased
+ by a fixed (scaled) value when there is no congestion outside of
+ Slow Start. Currently, the scaled value is 64KiB per 16.8ms.
+
+There is one caveat: what if no FLOW_UPDATE packet arrive at all?
+DCTCP (being TCP) will timeout at the RTO value, but this algorithm
+has no such mechanism at this point. The answer is that we currently
+do not monitor flow liveness from the flow allocator, but a
+Bidirectional Forwarding Detection (BFD)-like mechanism for flows
+should be added for QoS maintenance, and can serve to timeout the flow
+and reset it (meaning a full reset of the context). This is, however,
+not yet implemented.
+
+# MB-ECN in action
+
+From version 0.18 onwards[^3], the state of the flow -- including its
+congestion context -- can be monitored from the flow allocator
+statics:
+
+```bash
+$ cat /tmp/ouroboros/unicast.1/flow-allocator/66
+Flow established at: 2020-12-12 09:54:27
+Remote address: 99388
+Local endpoint ID: 2111124142794211394
+Remote endpoint ID: 4329936627666255938
+Sent (packets): 1605719
+Sent (bytes): 1605719000
+Send failed (packets): 0
+Send failed (bytes): 0
+Received (packets): 0
+Received (bytes): 0
+Receive failed (packets): 0
+Receive failed (bytes): 0
+Congestion avoidance algorithm: Multi-bit ECN
+Upstream congestion level: 0
+Upstream packet counter: 0
+Downstream congestion level: 48
+Downstream packet counter: 0
+Congestion window size (ns): 65536
+Packets in this window: 7
+Bytes in this window: 7000
+Max bytes in this window: 51349
+Current congestion regime: Multiplicative dec
+```
+
+I ran a quick test using the ocbr tool (modified to show stats every
+100ms) on a jFed testbed using 3 Linux servers (2 clients and a
+server) in star configuration with a 'router' (a 4th Linux server) in
+the center. The clients are connected to the 'router' over Gigabit
+Ethernet, the link between the 'router' and server is capped to 100Mb
+using ethtool[^4].
+
+Output from the ocbr tool:
+
+```
+Flow 64: 998 packets ( 998000 bytes)in 101 ms => 9880.8946 pps, 79.0472 Mbps
+Flow 64: 1001 packets ( 1001000 bytes)in 101 ms => 9904.6149 pps, 79.2369 Mbps
+Flow 64: 999 packets ( 999000 bytes)in 101 ms => 9882.8697 pps, 79.0630 Mbps
+Flow 64: 998 packets ( 998000 bytes)in 101 ms => 9880.0143 pps, 79.0401 Mbps
+Flow 64: 999 packets ( 999000 bytes)in 101 ms => 9887.6627 pps, 79.1013 Mbps
+Flow 64: 999 packets ( 999000 bytes)in 101 ms => 9891.0891 pps, 79.1287 Mbps
+New flow.
+Flow 64: 868 packets ( 868000 bytes)in 102 ms => 8490.6583 pps, 67.9253 Mbps
+Flow 65: 542 packets ( 542000 bytes)in 101 ms => 5356.5781 pps, 42.8526 Mbps
+Flow 64: 540 packets ( 540000 bytes)in 101 ms => 5341.5105 pps, 42.7321 Mbps
+Flow 65: 534 packets ( 534000 bytes)in 101 ms => 5285.6111 pps, 42.2849 Mbps
+Flow 64: 575 packets ( 575000 bytes)in 101 ms => 5691.4915 pps, 45.5319 Mbps
+Flow 65: 535 packets ( 535000 bytes)in 101 ms => 5291.0053 pps, 42.3280 Mbps
+Flow 64: 561 packets ( 561000 bytes)in 101 ms => 5554.3455 pps, 44.4348 Mbps
+Flow 65: 533 packets ( 533000 bytes)in 101 ms => 5272.0079 pps, 42.1761 Mbps
+Flow 64: 569 packets ( 569000 bytes)in 101 ms => 5631.3216 pps, 45.0506 Mbps
+```
+
+With only one client running, the flow is congestion controlled to
+about ~80Mb/s (indicating the queue limit at 16 packets may be a bit
+too low a bar). When the second client starts sending, both flows go
+quite quickly (at most 100ms) to a fair state of about 42 Mb/s.
+
+The IO graph from wireshark shows a reasonably stable profile (i.e. no
+big oscillations because of AIMD), when switching the flows on the
+clients on and off which is on par with DCTCP and not unexpected
+keeping in mind the similarities between the algorithms:
+
+{{<figure width="60%" src="/blog/news/20201212-congestion.png">}}
+
+The periodic "gaps" were not seen at the ocbr endpoint applicationand
+may have been due to tcpdump not capturing everything that those
+points, or possibly a bug somewhere.
+
+As said, a lot more work is needed analyzing this algorithm in terms
+of performance and stability[^5]. But I am feeling some excitement about its
+simplicity and -- dare I say it? -- elegance.
+
+Stay curious!
+
+Dimitri
+
+[^1]: Additive Increase increases the window size with 1 MSS each
+ RTT. Slow Start doubles the window size each RTT.
+
+[^2]: I'm pretty sure the kernel developers would if they could.
+[^3]: Or the current "be" branch for the less patient.
+[^4]: Using Linux traffic control (```tc```) to limit traffic adds
+ kernel queues and may interfere with MB-ECN.
+[^5]: And the prototype implementation as a whole!
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